CN110072795A - The method and apparatus of the status monitoring of ropes for lifting means - Google Patents
The method and apparatus of the status monitoring of ropes for lifting means Download PDFInfo
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- CN110072795A CN110072795A CN201780076495.8A CN201780076495A CN110072795A CN 110072795 A CN110072795 A CN 110072795A CN 201780076495 A CN201780076495 A CN 201780076495A CN 110072795 A CN110072795 A CN 110072795A
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- ropes
- bearing carrier
- analyzer module
- conductive
- electromagnetic wave
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B66—HOISTING; LIFTING; HAULING
- B66B—ELEVATORS; ESCALATORS OR MOVING WALKWAYS
- B66B7/00—Other common features of elevators
- B66B7/12—Checking, lubricating, or cleaning means for ropes, cables or guides
- B66B7/1207—Checking means
- B66B7/1215—Checking means specially adapted for ropes or cables
- B66B7/1223—Checking means specially adapted for ropes or cables by analysing electric variables
Landscapes
- Lift-Guide Devices, And Elevator Ropes And Cables (AREA)
- Investigating Or Analyzing Materials By The Use Of Electric Means (AREA)
- Maintenance And Inspection Apparatuses For Elevators (AREA)
Abstract
The present invention relates to a kind of method of the status monitoring of ropes for lifting means and a kind of state monitoring apparatus of the ropes for lifting means, it is preferable that the lifting means is the elevator for transporting passenger and/or cargo.Ropes (1) according to the present invention for lifting means, (22) device of status monitoring, wherein, the ropes (1), (22) include non-conductive coating layer (2) and be applied to ropes (1) in their longitudinal direction for carrying, (22) multiple adjacent conductive bearing carriers (3-6) of the load on, the multiple adjacent conductive bearing carrier (3-6) is embedded in coating (2) and in parallel with each other and is parallel to ropes (1), (22) extend to longitudinal direction, the coating (2) forms ropes (1), (22) surface simultaneously extends between adjacent bearing carrier (3-6), to which adjacent bearing carrier (3-6) is isolated from each other, described device includes control system (7), the control system (7) Including analyzer module (8), for generating and being inserted into the electromagnetic wave signal of propagation at least one the parallel conductor transmission line (14-15) formed by the conductive bearing carrier (3-6) and be used for detection and analysis Lai the reflection electromagnetic wave signal at least one parallel conductor transmission line (14-15) that freely the conductive bearing carrier (3-6) is formed.
Description
Technical field
The present invention relates to a kind of methods of the status monitoring of ropes for lifting means, and one kind is for being promoted
The device of the status monitoring of the ropes of equipment.The lifting means is preferably used for transporting the electricity of passenger and/or cargo
Ladder.
Background technique
Ropes generally include one or more bearing carriers, which is elongated on the longitudinal direction of rope
, each bearing carrier is formed in the whole length of rope continuous continual structure.Bearing carrier is capable of inciting somebody to action for rope
The component that the load on rope carries together is applied to along its longitudinal direction.Load, such as by the weight of rope suspensions, in rope
Longitudinal direction on cause tension on bearing carrier, which can be by the bearing carrier that is discussed from one end of rope one
It direct transfers and is delivered to the other end of rope.Rope may also include non-bearing component, such as elastic coating, cannot transmit in the above described manner
Tension.
In the prior art, there are such ropes, and wherein bearing carrier insertion the non-of such as polymer coating is led
In electrocoat, forms the surface of ropes and extend between adjacent bearing carrier, to mechanically and electrically should
Adjacent bearing carrier is isolated from each other.
For the ease of understanding the situation of rope, to improve the safety of lifting means, it has been proposed that bearing carrier
State monitoring.The visual inspection of inner tensile element is not typically possible, it is therefore desirable to carry out non-visual inspection.Existing
Have and has proposed that status monitoring is arranged by the electrical parameter of monitoring bearing carrier in technology.
For checking that a kind of known method of the state of tensile elements is the inspection based on resistance, based on tensile elements
The measurement of resistance.The variation of resistance or and the deviation of desired value be interpreted the damages of tensile elements.This method has some lack
Point.However, it has been found that the damage that can not ignore may cause the micro- of the resistance of the common tensile elements of such as wirerope etc
Small variation.Therefore, the sensitivity of the inspection based on resistance is unsatisfactory.
A kind of art methods of status monitoring for ropes are that conductive member is placed in rope.It can be with
By applying electric current to component come the state of testing conductive component.If damage occurs to being enough to destroy the degree of conductive member,
Then circuit disconnects.This method has some disadvantages.In the method, no qualitative information come indicate rope during use whether
Deterioration, because the first instruction is provided by the conductive member disconnected.In addition, this method is not provided about the damage along rope lengths
The information of position.
Summary of the invention
The purpose of the present invention is introduce a kind of method of the status monitoring of ropes for lifting means, and one kind
The state monitoring apparatus of ropes for lifting means, wherein the damage of the length about the ropes along lifting means
The information of bad position is provided.Furthermore, it is also proposed that advantageous embodiment, especially, wherein provide about lesion size
Qualitative information.
The new method of the status monitoring of the ropes for lifting means is proposed, the ropes include non-conductive
Coating and multiple adjacent conductive bearing carriers for carrying the load being applied in ropes in their longitudinal direction, institute
It states multiple adjacent conductive bearing carriers insertions in the coating and in parallel with each other and is parallel to the longitudinal direction side of ropes
Extend to ground, the coating forms the surface of ropes and extends between adjacent bearing carrier, so that adjacent be held
Mount components are isolated from each other, and in the method, generate the electromagnetic wave signal of propagation and insert it by the conductive carrying structure
At least one parallel conductor transmission line that part is formed, detect come that the freely conductive bearing carrier formed described at least one is flat
The reflection electromagnetic wave signal of column conductor transmission line, the electromagnetic wave signal detected described in analysis.It is thereby achieved that one or more
Above-mentioned advantage and/or purpose.These advantages are further promoted by other preferred feature and/or step described below
And/or purpose.
In the preferred embodiment of the method, the conduction bearing carrier is made of nonmetallic materials.
In the preferred embodiment of the method, the conduction bearing carrier is made of composite material, the composite material
Including the conductive reinforcement fibers in polymer substrate, the reinforcing fiber is preferably carbon fiber.
In institute's preferred embodiment, one or more parameters of the state for determining ropes are provided.
In a preferred embodiment, the information about damage position and/or impedance mismatching size is provided.
In a preferred embodiment, the information of the seriousness for quantifying defect is provided, the defect is, for example, fibre damage.
In a preferred embodiment, the one or more of parameters for receiving the state for determining ropes it
Afterwards, status monitoring movement is executed.
In a preferred embodiment, the method also includes following steps, for improving analyzer module and conductive carrying structure
Electrical contact between part: the end of ropes is cut;Remove the non-conducting material around carbon fiber;With metal coating exposure
Fiber, the metal such as copper or nickel;And the connecting interface of analyzer module is welded to being coated for ropes end
Exposed fibers on.
In a preferred embodiment, the method also includes following steps, for improving analyzer module and conductive carrying structure
Electrical contact between part: the end of ropes is cut;Remove the non-conducting material around carbon fiber;And by analyzer module
Connecting interface be clamped in the exposed fibers of ropes end.
In a preferred embodiment, the method also includes following steps, for improving analyzer module and conductive carrying structure
Electrical contact between part: the end of ropes is cut;Remove the non-conducting material around carbon fiber;With metal coating exposure
Fiber, the metal such as copper or nickel;The connecting interface of analyzer module is clamped to the coated sudden and violent of ropes end
On fiber exposure.
The new equipment of the status monitoring of the ropes for lifting means is proposed, the ropes include non-conductive
Coating and multiple adjacent conductive bearing carriers for carrying the load being applied in ropes in their longitudinal direction, institute
It states multiple adjacent conductive bearing carriers insertions in the coating and in parallel with each other and is parallel to the longitudinal direction side of ropes
Extend to ground, the coating forms the surface of ropes and extends between adjacent bearing carrier, so that adjacent be held
Mount components are isolated from each other, and described device includes control system, and the control system includes analyzer module, for generating propagation
Electromagnetic wave signal and the electromagnetic wave signal of propagation is inserted at least one parallel conductor formed by the conductive bearing carrier
Transmission line and at least one the described parallel conductor transmission for carrying out the freely conductive bearing carrier formation for detection and analysis
The reflection electromagnetic wave signal of line.
In the preferred embodiment of described device, the conduction bearing carrier is made of nonmetallic materials.
In the preferred embodiment of described device, the conduction bearing carrier is made of composite material, the composite material
Including the conductive reinforcement fibers in polymer substrate, the reinforcing fiber is preferably carbon fiber.
In the preferred embodiment of place described device, the analyzer module provides one for determining ropes state
A or multiple parameters.
In a preferred embodiment, analyzer module according to the present invention is signal generator/analyzer module, network
Analyzer module, scalar network analyzer unit or vector network analyzer unit.
In a preferred embodiment, the control system includes Condition Monitoring Unit, is provided for monitoring by analyzer module
One or more parameters, to determine the state of ropes.
In a preferred embodiment, described device includes connecting interface, for the first end in ropes by analyzer list
Member is connected to conductive bearing carrier.
In a preferred embodiment, described device includes one or more extra conductors, in the whole length of ropes
On continuously extend.
In a preferred embodiment, one or more of extra conductors and conductive bearing carrier material having the same.
In a preferred embodiment, described device includes additional connecting interface, for that will divide at the other end of ropes
Parser unit is connected to conductive bearing carrier.
In a preferred embodiment, described device includes at least one impedance being arranged at the other end of the ropes
Matching element, at least one described impedance matching element are connected between the end of the bearing carrier, for match it is described extremely
The impedance of a few parallel conductor transmission line.
In a preferred embodiment, the reflection electromagnetic wave signal other than repetitive peak with stable amplitude is being detected
When, it is flawless one or more parameters that the analyzer module, which provides the state for determining ropes,.
In a preferred embodiment, when detecting the reflection electromagnetic wave signal with defect instruction peak value, the analyzer
Unit provides one for determining the faulty state of ropes and the defect type for determining ropes and state
Or multiple parameters.
In a preferred embodiment, the analyzer module provides the information about damage position and/or impedance mismatching size.
In a preferred embodiment, the analyzer module provides the information for quantifying the seriousness of defect, the defect
E.g. fibre damage.
In a preferred embodiment, the ropes are band-like, i.e., width direction is bigger than thickness direction.
In a preferred embodiment, when receiving one or more of parameters for determining the state of ropes,
The monitoring unit executes status monitoring movement.
In a preferred embodiment, the analyzer is executed by changing signal form, signal amplitude and/or signal frequency
Multiple measurements.
In a preferred embodiment, the analyzer carries out the measurement for reaction distortion and attenuation effect.
In a preferred embodiment, the analyzer carries out the measurement of the impedance for matching parallel conductor transmission line.
Detailed description of the invention
It hereinafter, will the present invention will be described in more detail by example, with reference, in which:
Fig. 1 shows the dress of the status monitoring of the ropes according to an embodiment of the invention for lifting means
It sets.
Fig. 2 shows an examples of reflection electromagnetic wave signal according to an embodiment of the invention.
Fig. 3 shows the preferred internal structure of bearing carrier according to the present invention.
Fig. 4 shows the 3-D view of the section of bearing carrier according to the present invention.
Fig. 5 A shows the status monitoring of the ropes according to an embodiment of the invention for lifting means
Another device.
Fig. 5 B shows the status monitoring of the ropes according to an embodiment of the invention for lifting means
3rd device.
Fig. 5 C shows the status monitoring of the ropes according to an embodiment of the invention for lifting means
4th device.
Fig. 6 shows the dress of the status monitoring of the ropes for lifting means according to a fifth embodiment of the present invention
It sets, there is defect in ropes.
Fig. 7 shows another example of reflection electromagnetic wave signal according to a fifth embodiment of the present invention, should be in hoisting rope
There is defect in rope.
Fig. 8 shows the side of the status monitoring of the ropes according to an embodiment of the invention for lifting means
Method.
Fig. 9 shows according to an embodiment of the invention for improving the state of the ropes for lifting means
One example of the method for the electrical contact arrangement between the conductive bearing carrier and analyzer module of the device of detection.
Figure 10 shows according to an embodiment of the invention for improving the shape of the ropes for lifting means
Another example of the method for electrical contact arrangement between the conductive bearing carrier and analyzer module of the device of state monitoring.
Figure 11 shows according to an embodiment of the invention for improving the shape of the ropes for lifting means
The third example of the method for electrical contact arrangement between the conductive bearing carrier and analyzer module of the device of state detection.
With reference to the accompanying drawings with associated detailed description, aforementioned aspects of the invention, feature and advantage be will be evident.
Specific embodiment
Fig. 1 shows the dress of the status monitoring of the ropes according to an embodiment of the invention for lifting means
It sets.Ropes 1 be it is band-like, i.e., it is bigger than thickness direction in the direction of the width, and have first end and the other end 16.It is promoted
Rope 1 is applied to the load in ropes 1 on the longitudinal direction including non-conductive coating layer 2 and for being carried on ropes 1
Multiple conductive bearing carrier 3-6, the width direction of the non-conductive coating layer 2 and multiple conduction bearing carrier 3-6 in ropes 1
It is upper adjacent.It is put down each other incessantly in bearing carrier 3-6 insertion non-conductive coating layer 2 and in the length of entire ropes 1
Row ground and the longitudinal direction extension for being parallel to ropes 1.Coating 2 forms the surface of ropes 1 and in adjacent carrying
Extend between component 3-6, so that mechanically and electrically they be isolated from each other.The conduction bearing carrier 3-6 can be by non-
Metal material is made.The conduction bearing carrier 3-6 can be made of composite material, and the composite material includes polymer substrate
In conductive reinforcement fibers, the reinforcing fiber is preferably carbon fiber.
The device of the status monitoring of the ropes for lifting means of embodiment according to the present invention shown in FIG. 1 is also
Including the control system 7 for controlling lifting means.Control system 7 according to the device proposed further includes analyzer module 8,
The analyzer module 8 can generate the electromagnetic wave signal of propagation and the electromagnetic wave signal of propagation is inserted into the conductive carrying structure
Part 3-6 and it is able to detect and analyzes the reflection electromagnetic wave signal from the conductive bearing carrier 3-6.According to the present invention point
Parser unit 8 can be signal generator/analyzer module 8 or network analyser unit 8, for example, scalar network analyzer list
Member 8 or vector network analyzer unit 8.In alternative embodiments, signal generator, power divider, orientation can also be used
Coupler and oscillograph directly measure in the time domain.In alternative embodiments, generated signal is in showing for reference
It is separated between rope in wave device and test;Directional coupler is only used for the wave of sensing reflection travelled rearwardly, and is fed
It is analyzed to oscillograph.It can also include Condition Monitoring Unit 9 according to the control system 7 of the device proposed, for monitoring
The one or more parameters provided by analyzer module 8, to determine the state of ropes 1.
The device proposed have connecting interface 10-13, at the other end 16 of ropes 1 by analyzer module
8 are connected to conductive bearing carrier 3-6.In the state prison of the ropes for lifting means of the embodiment according to the present invention
In the device of survey, the first parallel conductor transmission line 14 is formed with using two individual conductive bearing carriers 3,4.Correspondingly, make
The second parallel conductor transmission line 15 is formed with two individual conductive bearing carriers 5,6.Therefore, in same ropes 1
Generate two transmission lines 14,15 adjacent to each other.
In alternative embodiments of the present invention, each transmission line includes a conduction in multiple conductive bearing carrier 3-6
Bearing carrier 3-6 and at least one additional metal or non-metal conductor, at least one additional metal or non-metal conductor
It is embedded in dielectric protective coating or using bracket (standoff) separation in the free air outside dielectric protective coating.
The extra conductor of material identical as carrying conductor (preferably carbon fiber) can be conducive to keep fuel factor symmetrical, such as thermal expansion or electricity spy
The temperature dependency of property.The transmission line can be coaxial with the conductive shielding part around carbon fiber element.This will be reduced from outer
The interference in portion source.The transmission line can be microstrip line, with plate of conductive material, such as extended in parallel with carbon fiber element
Copper.In this way, single carbon fiber element can be checked one by one, and independent of the adjacent carbons fibre element that may be ruptured.The biography
Defeated line can be strip line, carbon fiber element either side tool there are two earth plate, with microstrip line compared with preferably every
From.The transmission line is also possible to cage line, has multiple parallel conductors around center conductor, but multiple parallel conductors are unlike same
The shielding of axis is in contact with each other like that.In addition, transmission line may be dissipated due to caused by the phase velocity of frequency dependence and undergo damage
Consumption.The transmission line is also possible to the transmission line of load, to increase inductance and to meet the Heaviside condition of distortionless line.
The load can be it is continuous or fragment shape, for example, by making conductor that the material with high magnetic permeability be used to wrap up.
In the device of the status monitoring of the ropes for lifting means of embodiment according to the present invention, propagation
Electromagnetic wave signal, such as AC voltage/current signal are generated and are inserted by analyzer module 8, the AC voltage/current letter
It number is inserted into the conductive bearing carrier 3-6, to propagate in positive z direction according to generally acknowledged one-way wave equation.With electricity
Magnetostatic wave signal, such as along the first parallel conductor transmission line 14 or the alternating voltage/electricity propagated along the second parallel conductor transmission line 15
The other end 16 that signal reaches ropes 1 is flowed, a part of the signal will be reflected back as reflection electromagnetic wave signal.
The reflection electromagnetic wave signal reflected from the other end 16 of ropes 1 is along the first parallel conductor transmission line 14 or along the
Two parallel conductor transmission lines 15, which are propagated back to, to be come, and by 8 detection and analysis of analyzer module.After an analysis, analyzer module 8 mentions
It is used to be monitored by Condition Monitoring Unit 9 for one or more parameters.It has been received in Condition Monitoring Unit 9 for determining
After the defect type of ropes 1 and one or more parameters of state, Condition Monitoring Unit 9 executes status monitoring movement.
In another alternate embodiment of the invention, exists and be connected to conduction at the other end 16 of ropes 1 and hold
The other connecting interface for being also connected to analyzer module 8 of mount components 3-6.It is that can invert in the benefit that both ends are attached
Sense, and if there is no failure, then the signal observed should appear the same as.This can be used for measuring transmission coefficient
And systematic error is found in setting.Even if failure makes first end and the other end 16 be all connected to analyzer list close to either end
First 8 (for example, network analysers 8) be also it is beneficial because the travel distance of wave is minimized, power transmission loss is also most
Smallization.
Fig. 2 shows an examples of reflection electromagnetic wave signal according to an embodiment of the invention.Shown in Fig. 2 shows
In example, reflection electromagnetic wave signal 17 is reflected from the other end 16 of ropes 1.In the reflection according to the embodiment proposed
In electromagnetic wave signal 17, the reflected repetitive peak 18,19 of the other end 16 from ropes 1 can detecte.Due to removing
Except the reflected repetitive peak 18,19 of the other end 16 of ropes 1, the reflection electromagnetic wave signal 17 that detects
Amplitude is stable, so analyzer module 8 can provide one or more parameters to Condition Monitoring Unit 9, is promoted with determining
The state of rope 1 is flawless.
Fig. 3 shows the preferred internal structure of bearing carrier according to the present invention.In fig. 3 it is shown that bearing carrier 3
Width direction w and thickness direction t.In Fig. 3, the bearing carrier observed on the longitudinal direction l of bearing carrier 3 is particularly illustrated
3 cross section.Rope can alternatively with the bearing carrier 3 of some other quantity, or than disclosed in figure more or more
It is few.
Bearing carrier 3-6 is made of composite material, which includes the reinforcing fiber F being embedded in polymer substrate m.
Reinforcing fiber F is more specifically distributed in polymer substrate m and is combined together by polymer substrate, in particular so that being formed
Elongated rod-like element.Therefore, each bearing carrier 3-6 is a solid elongated rod-like element.Reinforcing fiber F is preferably substantially uniform
Ground is distributed in polymer substrate m.The bearing carrier with homogenous properties and structure is realized on entire cross section as a result,.With
This mode, it may also be ensured that every fiber can be contacted and be combined with matrix m.The reinforcing fiber F is most preferably carbon fiber,
Because they are conduction and have excellent performance in terms of bearing capacity, weight and tensible rigidity, this makes their spies
It Shi Yongyu not ele-vator hoisting ropes.Alternatively, the reinforcing fiber F can be any other conductive fibrous material.Matrix m is preferred
Including epoxy resin, but alternative materials can be used according to preferred property.Preferably, each bearing carrier 3-6's is basic
Upper all reinforcing fiber F are parallel to the longitudinal direction of bearing carrier 3-6.Therefore, when each bearing carrier is parallel to ropes 1
Longitudinal direction orientation when, fiber is also parallel with the longitudinal direction of ropes 1.Therefore, the fibre in final ropes 1
Dimension will be aligned with power when ropes 1 is pulled, which ensure that the structure provides high tensible rigidity.This is for working as ropes 1
The no problem behavior of internal structure is realized when bending, especially internal motion is also advantageous.
The fiber F used in a preferred embodiment relative to each other be substantially it is non-warping, this for they provide and
The parallel orientation of the longitudinal direction of ropes 1.This is with conventional distortion elevator rope on the contrary, in conventional distortion elevator
In rope, the windup-degree that line or fiber are initially strongly distorted and usually spend with 15 to 30, these conventional distortion elevator ropes
Therefore fiber/harness of rope has a possibility that direction more straight tectonic transition in the case where stretching, this makes these ropes
There is high elongation rate under tension and lead to nonintegrated structure.
Reinforcing fiber F is preferably long continuous fiber on the longitudinal direction of bearing carrier, and fiber F is preferably for holding
The whole length of mount components 3-6 and ropes 1 is continuous.Therefore, facilitate bearing capacity, good electric conductivity and carrying structure
The manufacture of part 3-6.As much as possible, fiber F is parallel to the entire length of ropes 1 being longitudinally orientated so that for ropes 1
The cross section of the cross section of degree, bearing carrier 3-6 can be continuous roughly the same.Therefore, it when bearing carrier 3-6 is bent, is holding
Substantive relative motion will not occur inside mount components 3-6.
As described above, reinforcing fiber F preferably substantially equably, particularly is distributed as uniformly as possible in above-mentioned carrying
In component 3-6, so that bearing carrier 3-6 is homogeneous as far as possible in the widthwise direction thereof.The advantages of structure proposed, is
Matrix m around reinforcing fiber F keeps the insertion of reinforcing fiber F to be basically unchanged.It makes to be applied to fibre using its slight elasticity
The distribution of power in dimension is equal, reduces the inter deterioration of Fiber-Fiber contact and ropes, so as to improve hoisting rope
The service life of rope 1.Single fiber F is distributed as uniformly as possible in composite interstitial substance m therein and is most preferably made of epoxy resin,
It has good adhesiveness to reinforcing fiber F, and known its advantageously acts on together with carbon fiber.Alternatively, for example can be with
Using polyester or vinyl esters, but any other suitable alternative materials also can be used.Fig. 3 is shown inside circle to be mentioned
Rise the partial cross-section close to its surface of the bearing carrier 3-6 observed on the longitudinal direction of rope 1.The increasing of bearing carrier 3-6
Strong fiber F is preferably organized in polymer substrate m according to the cross section.Rest part (the unshowned portion of bearing carrier 3-6
Point) there is similar structure.
Fig. 4 shows the 3-D view of the section of bearing carrier according to the present invention.As can be seen that holding from Fig. 3 and Fig. 4
How each reinforcing fiber F of mount components 3 is distributed generally uniformly in polymer substrate m, and polymer substrate m is around enhancing
Fiber F.Polymer substrate m is filled in the region between each reinforcing fiber F and substantially by all enhancing inside matrix m
Fiber F is bonded to each other as uniform solid matter.Between each reinforcing fiber F (preferably each of which) and matrix m
There are chemical bond, the advantages of chemical bond is the uniformity of structure.It is special in order to improve the chemical bonding of reinforcing fiber Yu matrix m
It is not to enhance the chemical bond between reinforcing fiber F and matrix m, every kind of fiber can have thin coating, for example, enhancing
Bottom coating (primer) (not shown) in actual fibers structure between fibre structure and polymer substrate m.But it is this
Shallow layer is not required.The property of polymer substrate m can also optimize, because it is common in polymer technology.Example
Such as, matrix m may include base polymeric material (such as epoxy resin) and additive, finely tune the property of base polymer,
To optimize the property of matrix.Polymer substrate m is preferably hard inelastic body, because can for example reduce in this case
The risk of buckling.However, polymer substrate must be not necessarily inelastic body, for example, if the shortcomings that this material be considered
It is acceptable or unrelated with desired use.In this case, polymer substrate m can be made of elastomeric material, such as
Polyurethane or rubber.Reinforcing fiber F in the polymer matrix here mean that each reinforcing fiber F with polymer substrate m that
This is combined, for example, then solidifying the fluid by the fluent material that they are immersed polymer substrate together by the fabrication stage
Material.In this case, the gap for each reinforcing fiber being bonded to each other with polymer substrate includes the polymer of matrix.With
This mode, a large amount of reinforcing fibers distribution being bonded to each other on the longitudinal direction of ropes is in the polymer matrix.As above
Described, reinforcing fiber is preferably substantially evenly distributed in polymer substrate m, thus when the cross-sectional direction in ropes
When upper observation, bearing carrier homogeneous as far as possible.In other words, the fibre density in the cross section of bearing carrier 3-6 is therefore basic
On do not change.Each reinforcing fiber of bearing carrier 3-6 is mainly surrounded by polymer substrate m, but due to same with polymer
When dipping fiber when control fiber position relative to each other be difficult, it is thus possible to random Fiber-Fiber contact occurs,
And on the other hand, from the viewpoint of the function of technical solution, do not need to completely eliminate random Fiber-Fiber contact.So
And, if it is desired to their random generation is reduced, each reinforcing fiber F can be coated in advance with the material of matrix m, so that described
The coating of the polymer material of matrix is before each reinforcing fiber F and polymer material are brought together after and are combined together
(for example, before they immerse liquid matrix material) has been centered around each of which.
As described above, the matrix m of bearing carrier 3-6 most preferably its material property is hard.Hard matrix m facilitates
Reinforcing fiber F is supported the reinforcing fiber F buckling of bending rope to be prevented, because of stiff materials especially when ropes are bent
Effectively support fiber F.In order to reduce buckling and promote the small-bend radius etc. of bearing carrier 3-6, therefore preferred polymers base
Matter m be it is hard, it is especially stiff.Optimal material selection for matrix is epoxy resin, polyester, phenoplasts or ethylene
Base ester.Polymer substrate m is preferably hard and its elastic modulus E is made to be more than 2GPa, most preferably more than 2.5GPa.This
In the case of, elastic modulus E is preferably in the range of 2.5-10GPa, most preferably in the range of 2.5-3.5GPa.Commercially available matrix
The optional object of a variety of materials of m can provide these material properties.
Preferably, 50% or more of the surface area of the cross section of bearing carrier 3-6 is above-mentioned conductive reinforcement fibers.As a result,
It may insure good electric conductivity.Fiber F will randomly be in contact with each other along its length, to be inserted into the electromagnetic wave in bearing carrier
Signal will be propagated in the substantially entire cross section of bearing carrier.More precisely, the surface of the cross section of bearing carrier 3-6
Long-pending 50%-80% is preferably above-mentioned reinforcing fiber, and most preferably 55%-70% is above-mentioned reinforcing fiber, and essentially all
Remaining surface area is all polymer substrate.In this way, be conducive to the electric conductivity and longitudinal rigidity of bearing carrier 3-6, but
It is to have enough host materials that fiber F is effectively bonded to each other.Most preferably, it executes in this way so that about 60% surface area is
Reinforcing fiber, about 40% is host material.
Fig. 5 A shows the status monitoring of the ropes according to an embodiment of the invention for lifting means
Another device.Ropes 1 be it is band-like, i.e., it is bigger than thickness direction in the direction of the width, and have first end and the other end
16.Ropes 1 are applied to ropes 1 on the longitudinal direction including non-conductive coating layer 2 and for being carried on ropes 1
Load multiple conductive bearing carrier 3-6, the width of the non-conductive coating layer 2 and multiple conduction bearing carrier 3-6 in ropes 1
It spends adjacent on direction.Bearing carrier 3-6 be embedded in non-conductive coating layer 2 in and in the length of entire ropes 1 incessantly
In parallel with each other and be parallel to ropes 1 longitudinal direction extend.Coating 2 forms the surface of ropes 1 and adjacent
Bearing carrier 3-6 between extend, so that mechanically and electrically they are isolated from each other.The conduction bearing carrier 3-6 can
To be made of nonmetallic materials.The conduction bearing carrier 3-6 can be made of composite material, and the composite material includes polymerization
Conductive reinforcement fibers (F) in object matrix (m), the reinforcing fiber (F) is preferably carbon fiber.
The status monitoring of the ropes for lifting means of another embodiment according to the present invention proposed
Device further includes the control system 7 for controlling lifting means, and the control system 7 has analyzer module 8 and status monitoring
Unit 9.Analyzer module 8 can generate the electromagnetic wave signal of propagation and the electromagnetic wave signal of propagation is inserted into the conduction and hold
Mount components 3-6, and it is able to detect and analyzes the reflection electromagnetic wave signal from the conductive bearing carrier 3-6.Status monitoring
Unit 9 can monitor the one or more parameters provided by analyzer module 8, to determine the state of ropes 1.
There is the company for the conductive bearing carrier 3-6 for being connected to ropes 1 according to the analyzer module 8 of the device proposed
Connection interface 10-13.In the device of the status monitoring of the ropes for lifting means of embodiment according to the present invention, make
The first parallel conductor transmission line 14 is formed with two individual conductive bearing carriers 3,4.Correspondingly, it is individually led using two
Electric bearing carrier 5,6 is formed with the second parallel conductor transmission line 15.Therefore, it is generated adjacent to each other in same ropes 1
Two transmission lines 14,15.
In the device of the status monitoring of the ropes for lifting means according to another embodiment of the present invention, also
Including at least one impedance matching element 200,205 being arranged at the other end 16 of ropes 1.In at least one described resistance
In anti-matching element 200,250, an element 200 is connected between bearing carrier 3 and 4 end, parallel for matching first
The impedance of conductor transmission line 14.Correspondingly, at least one described impedance matching element 200,250, an element 205 is connected
Between bearing carrier 5 and 6 end, for matching the impedance of the second parallel conductor transmission line 15.
In the state monitoring apparatus of the ropes for lifting means according to another embodiment of the invention, pass
The electromagnetic wave signal broadcast, for example, AC voltage/current signal is generated and is inserted by analyzer module 8, the alternating voltage/electricity
Stream signal is inserted into the conductive bearing carrier 3-6, to be propagated in positive z direction according to generally acknowledged one-way wave equation.With
Electromagnetic wave signal, such as along the first parallel conductor transmission line 14 or along the second parallel conductor transmission line 15 propagate alternating current
When pressure/current signal arrival ropes 1 other end 16 and at least one described impedance matching element 200,205, the letter
Number a part will back reflect as reflection electromagnetic wave signal.The reflection electromagnetic wave reflected from the other end 16 of ropes 1
Signal is propagated back to along the first parallel conductor transmission line 14 or along the second parallel conductor transmission line 15, and is examined by analyzer module 8
It surveys and analyzes.
The parameter of measurement can be scattering parameter, and which depict the scores of reflection/transmission wave relevant to incidence wave.If
Input impedance and the characteristic impedance of rope mismatch, then reflection and thoroughly will occur for the interface between input cable and rope
It penetrates.If the transmission line being made of two conductors is in end short circuit or keeps opening a way, reflection coefficient will be respectively -1 or+1,
It will be totally reflected in the case where being with or without phasing back.Also, if using at least one impedance matching member
The terminal of part 200,205 is made into the load of matching characteristic impedance, then mismatch is not present and will not reflect.It is analyzing
Later, analyzer module 8 provides one or more parameters for being monitored by Condition Monitoring Unit 9.In Condition Monitoring Unit 9
After the one or more parameters for receiving the defect type and state for determining ropes 1, Condition Monitoring Unit 9 is executed
Status monitoring movement.
Fig. 5 B shows the status monitoring of the ropes according to an embodiment of the invention for lifting means
3rd device.The device of the status monitoring of the ropes for lifting means presented in Fig. 5 B is similar to shown in Fig. 1
Device, in addition to providing the extra conductor 210 continuously extended in the whole length of ropes 1.According to being proposed
The analyzer module 8 of device have and be connected to the connecting interface of extra conductor 210.
Fig. 5 C shows the status monitoring of the ropes according to an embodiment of the invention for lifting means
4th device.In device shown in Fig. 5 C for the status monitoring of the ropes of lifting means, provide one it is additional
Conductor 211-214, extend beside each conductive bearing carrier 3-6 and in the whole length of ropes 1 not
Ground is disconnected to extend.There is the connecting interface for being connected to extra conductor 211-214 according to the analyzer module 8 of the device proposed.
In the 4th device of the status monitoring of the ropes for lifting means of embodiment according to the present invention, shape
An individual conductive bearing carrier 3-6 is used at parallel conductor transmission line 151-154, each conductor transmission line 151-154
With an extra conductor 211-214.
The extra conductor 210-214 presented in Fig. 5 B-5C can be metal or non-metal conductor.Extra conductor 210-214
It can be embedded in the free air in dielectric protective coating or using the outside of bracket separation.Extra conductor 210-214 can be with
With conductive bearing carrier 3-6 material having the same.Extra conductor 210-214 can be made of nonmetallic materials.Extra conductor
210-214 can be made of composite material, which includes the conductive reinforcement fibers (F) in polymer substrate (m), described
Reinforcing fiber (F) is preferably carbon fiber.
Fig. 6 shows the dress of the status monitoring of the ropes for lifting means according to a fifth embodiment of the present invention
It sets, there is defect in ropes.Device shown in Fig. 6 for the status monitoring of the ropes of lifting means is similar
The device shown in Fig. 1, in addition to existing defects 23 in the first parallel conductor transmission line 14 of the defect ropes 22 of Fig. 6.
Defect ropes 22 are partly disconnected from the defects of middle section of defect ropes 22 23.
In the status monitoring of the ropes for lifting means of the 5th proposed embodiment according to the present invention
In device, there is defect, the electromagnetic wave signal of propagation in ropes, such as AC voltage/current signal is by analyzer list
Member 8 is generated and is inserted into, and the AC voltage/current signal is inserted into the conductive bearing carrier 3-6, according to generally acknowledged list
It is propagated in positive z direction to wave equation.It is passed with electromagnetic wave signal, such as along the first parallel conductor transmission line 14 of defect
The AC voltage/current signal broadcast reaches lacking in the middle section of the conductive bearing carrier 3 of the first parallel conductor transmission line 14
When falling into 23, a part of the signal will reflect back into the first part of the electromagnetic wave signal as reflection and the signal
Rest part by continue towards defect ropes 22 end 24.
Hereafter, the rest part of electromagnetic wave signal is from the defect 23 further along defect the first parallel conductor transmission line
14 and defect ropes 22 end 24 propagate.At the end of defect ropes 22 24, its remaining part of electromagnetic wave signal
Point second part as reflection electromagnetic wave signal will be reflected from the end of defect ropes 22 24.From defect hoisting rope
The first part for the reflection electromagnetic wave signal that rope 22 reflects and second part are propagated back to come along the first parallel conductor transmission line 14, and
It is detected as reflection electromagnetic wave signal and is analyzed by analyzer module 8.In addition, in mentioning for lifting means according to the present invention
In the device for rising the status monitoring of rope, the lowpass frequency scanning mould of analyzer module 8 (such as network analyser) can be used
Formula.This does not only give the information of impedance mismatch, and giving discontinuity is capacitive or inductive information, from
And give the instruction of damaged type.
After an analysis, analyzer module 8 provides one or more parameters for being monitored by Condition Monitoring Unit 9.
Condition Monitoring Unit 9 have been received the state for determining ropes 22 it is faulty and for determine ropes 1,
After 22 defect type and one or more parameters of state, Condition Monitoring Unit 9 executes status monitoring movement.
The device of the status monitoring of ropes according to the present invention for lifting means can be used for monitoring ropes
1, a variety of different types of defects in 22, a variety of different types of defects include porosity, dry fibers, unsuitable solid
Change, fiber it is wavy/misalign, MATRIX CRACKING, layering, microcreping, kink, fibre substrate removing, fiber failure, fatigue differentiation and
Damage Evolution.
As long as there are discontinuities for the electrical characteristics of parallel conductor transmission line 14,15, the electromagnetic wave signal of current propagation will
The electromagnetic wave for being separated into reflection electromagnetic wave and being propagated further.Therefore, by the reflection electromagnetic wave of 8 detection and analysis of analyzer module
Signal may include never with several reflection electromagnetic wave signal sections of transmission line discontinuity point reflection.
Analyzer module 8 analyzes reflection electromagnetic wave signal and gives the damage about influence electromagnetic property, about damage
The information of position and the size about impedance mismatch.With the help of the present invention, defect, such as fibre damage, it is serious
Property can quantify.
It can indicate that analyzer module 8 executes multiple measurements or analyzer module 8 can be performed automatically multiple measurements.Very
Thousands of measurements can extremely be carried out.In measurement, electromagnetic noise source (such as motor) can be closed during measurement, without
The operation of elevator is interfered too much.In the multiple measurement, analyzer module 8 can be by changing such as signal form, letter
Number amplitude and/or signal frequency propagate electromagnetic wave signal caused by changing.Furthermore, it is possible to indicate that analyzer module 8 is analyzed
Multiple measurements in frequency domain are to be used for reaction distortion and attenuating.In addition, analyzer module 8 can be executed to generated
The change of electromagnetic wave signal is propagated with the change of the impedance for matching parallel conductor transmission line 14,15.
Fig. 7 shows another example of reflection electromagnetic wave signal according to a fifth embodiment of the present invention, in ropes
In have defect.According to the defect ropes 22 of the embodiment proposed from the middle section of defect ropes 22
One defect 23 partly disconnects.In the example shown in Fig. 7, the first part of reflection electromagnetic wave signal passes from the first parallel conductor
The defects of middle section of conductive bearing carrier 3 of defeated line 14 23 reflects, the second part of reflection electromagnetic wave signal from
The end 24 of defect ropes 22 reflects.The first part of the reflection electromagnetic wave signal reflected from defect ropes 22
It is propagated back to along the first parallel conductor transmission line 14 with second part, and is detected as reflection electromagnetic wave signal and by analyzer list
Member 8 is analyzed.
In the reflection electromagnetic wave signal 25 according to the 5th embodiment proposed, abnormal repetitive peak can detecte
26-30 indicates the defects of middle section of defect ropes 22 23.Furthermore, it is possible to from defect ropes 22
The reflected abnormal repetitive peak 26-30 detected in the defects of middle section 23 detects the defect 23.
Due to that can indicate peak from the 25 detection and analysis defect of reflection electromagnetic wave signal detected by analyzer module 8
Value 26-30, therefore analyzer module 8 provides one or more parameters for determining defect ropes to Condition Monitoring Unit 9
22 defect type and state.
Fig. 8 shows the side of the status monitoring of the ropes according to an embodiment of the invention for lifting means
Method.In state monitoring method according to an embodiment of the invention, analyzer module 8 generates first and transmits 31 propagation
Electromagnetic wave signal is more to the load for bearing to be applied on the longitudinal direction of ropes 1,22 in ropes 1,22
A conduction bearing carrier 3-6, the conduction bearing carrier 3-6 form parallel conductor transmission line 14,15.Hereafter, analyzer module 8
The reflection electromagnetic wave signal 17,25 that detection 32 is reflected back along the parallel conductor transmission line 14,15.After a test, described
The reflection electromagnetic wave signal 17,25 that the analysis of analyzer module 8 33 detects.
After executing inserting step 31, detection 32 and analysis 33, analyzer module 8 may or may not continue 34 progress
Another one-shot measurement simultaneously repeats step 31-33.It can indicate that analyzer module 8 executes multiple measurements or analyzer module 8 can be with
Automatically multiple measurements are executed.In the multiple measurement, analyzer module 8 can be by changing such as signal form, signal width
Degree and/or signal frequency propagate electromagnetic wave signal caused by changing.In addition, analyzer module 8 can be executed to produced
Propagation electromagnetic wave signal change with the change of the impedance for matching parallel conductor transmission line 14,15.
After by repeating the enough measurements of step 31-33 progress, analyzer module 8 provides one or more parameters
35 give Condition Monitoring Unit 9, for determining the defect type and state of ropes 1,22.It is receiving for determining hoisting rope
After the defect type of rope 1,22 and one or more parameters of situation, Condition Monitoring Unit 9 executes the movement of 36 status monitorings.
Fig. 9 shows according to an embodiment of the invention for improving the state of the ropes for lifting means
One example of the method for the electrical contact arrangement between the conductive bearing carrier and analyzer module of the device of detection.According to this
It is first in the method for improving the electrical contact arrangement between analyzer module and conductive bearing carrier of one embodiment of invention
First in the case where being layered ropes 1,22, the end of 37 ropes 1,22 is cut.Ropes 1,22 ends
Cutting 37 can be completed for example with high speed grinding disk.In cutting 37 techniques, it is described to prevent that water or ethyl alcohol can be used as coolant
The blocking of high speed grinding disk and prevent hoisting rope 1,22 polymer substrate heating.
After the cutting 37 of ropes 1,22 ends, around carbon fiber remove 38 for example thermoplastic polyurethane or its
The non-conducting material and polymer substrate of his thermoplastic elastomer (TPE).Removing 38 can be for example using for example utilizing oxy-acetylene or class
It is carried out like flame or using the repetition Rapid Heating Cyclic of induction coil.
It is cutting 37 ropes 1,22 ends and is removing 38 after the non-conducting material around carbon fiber, will expose
The fiber metal of such as copper or nickel coating 39, such as use electro-deposition.
In the example of technique for coating 39 exposed fibers, electrolyte can be by copper sulphate (200g/ liter
CuSO45H2O it) is formed with the aqueous solution of sulfuric acid (50g/ rises H2SO4).In the coating processes, high-purity copper can be used
Anode, and the conductive bearing carrier that ropes can be used feeds the electric current fed from the other end as cathode.Aluminium foil
It can be used for improving the electrical connection of cathode.2-20A/dm can be used2Current density, the difference in Electrode Potential of 0.2-6V and 1 hour
Sedimentation time.
37 ropes 1,22 ends are being cut, the non-conducting material around carbon fiber is removed and are coating 39 exposures
After fiber, the connecting interface 10-13 of analyzer module 8 directly welds the 40 coated exposures for arriving ropes 1,22 ends
On fiber.
Figure 10 shows according to an embodiment of the invention for improving the shape of the ropes for lifting means
Another example of the method for electrical contact arrangement between the conductive bearing carrier and analyzer module of the device of state detection.In basis
In the method for improving the electrical contact arrangement between analyzer module and conductive bearing carrier of one embodiment of the present of invention,
First in the case where being layered ropes 1,22, the end of 37 ropes 1,22 is cut.Ropes 1,22 ends
Cutting 37 can for example with high speed grinding disk complete.In cutting 37 techniques, water or ethyl alcohol can be used as coolant to prevent
It states the blocking of high speed grinding disk and prevents the heating of the polymer substrate of hoisting rope 1,22.
After the cutting 37 of ropes 1,22 ends, around carbon fiber remove 38 for example thermoplastic polyurethane or its
The non-conducting material and polymer substrate of his thermoplastic elastomer (TPE).Removing 38 can be for example using for example utilizing oxy-acetylene or class
It is carried out like flame or using the repetition Rapid Heating Cyclic of induction coil.
After cutting the non-conducting material around 37 ropes 1,22 ends and 38 carbon fibers of removal, analyzer list
The exposure that the connecting interface 10-13 of member 8 is for example directly clamped 41 to ropes 1,22 ends by using threaded screw is fine
In dimension.In the connecting interface 10-13, soft copper or aluminium foil can be used to improve connection.
Figure 11 shows according to an embodiment of the invention for improving the shape of the ropes for lifting means
The third example of the method for electrical contact arrangement between the conductive bearing carrier and analyzer module of the device of state detection.In basis
In the method for improving the electrical contact arrangement between analyzer module and conductive bearing carrier of one embodiment of the present of invention,
First in the case where being layered ropes 1,22, the end of 37 ropes 1,22 is cut.Ropes 1,22 ends
Cutting 37 can for example with high speed grinding disk complete.In cutting 37 techniques, water or ethyl alcohol can be used as coolant to prevent
It states the blocking of high speed grinding disk and prevents the heating of the polymer substrate of hoisting rope 1,22.
After the cutting 37 of ropes 1,22 ends, around carbon fiber remove 38 for example thermoplastic polyurethane or its
The non-conducting material and polymer substrate of his thermoplastic elastomer (TPE).Removing 38 can be for example using for example utilizing oxy-acetylene or class
It is carried out like flame or using the repetition Rapid Heating Cyclic of induction coil.
It is cutting 37 ropes 1,22 ends and is removing 38 after the non-conducting material around carbon fiber, will expose
The fiber metal of such as copper or nickel coating 39, such as use electro-deposition.
37 ropes 1,22 ends are being cut, the non-conducting material around carbon fiber is removed and are coating 39 exposures
After fiber, the connecting interface 10-13 of analyzer module 8 for example directly clamped by using threaded screw 41 to ropes 1,
In the coated exposed fibers of 22 ends.In the connecting interface 10-13, soft copper or aluminium foil can be used to improve and connect
It connects.
In the illustrated embodiment, bearing carrier 3-6 is substantially rectangle.However, this is not required, because can be with
Use alternative form.The composite component 3-6 can be manufactured for example in any known fashion, such as with WO2009090299A1
Shown in mode manufacture.
In the shown embodiment, rope 1 includes four bearing carrier 3-6.Certainly, alternative configuration is possible, wherein should
Device is realized with the rope for the bearing carrier 3-6 for being provided with some other quantity.
When referring to electric conductivity, in this application, refer to conductance electrical property.
It should be understood that above description and attached drawing are only intended to the best side for instructing manufacture and use known for inventor of the invention
Formula.It will be apparent to one skilled in the art that present inventive concept can be realized in various ways.Therefore, it is not departing from
It, can be with modifications or changes the above embodiment of the present invention, according to the above instruction such as those skilled in the art in the case where the present invention
Understood.It will be understood, therefore, that the present invention and embodiment are not limited to above-mentioned example, but in claim and its can wait
Change in the range of jljl.
Claims (30)
1. a kind of ropes (1) for lifting means, (22) status monitoring method, the ropes (1), (22)
Including non-conductive coating layer (2) and for carry be applied in their longitudinal direction ropes (1), load on (22) it is multiple
Adjacent conductive bearing carrier (3-6), the multiple adjacent conductive bearing carrier (3-6) is embedded in coating (2) and that
This in parallel and be parallel to ropes (1), (22) longitudinal direction extend, the coating (2) forms ropes
(1), the surface of (22) and extend between adjacent bearing carrier (3-6), thus by adjacent bearing carrier (3-6) each other every
From in the method
It generates the electromagnetic wave signal propagated and is inserted into (31) and arrive at least one formed by the conductive bearing carrier (3-6)
A parallel conductor transmission line (14-15),
It detects (32) and carrys out at least one parallel conductor transmission line (14- that freely the conductive bearing carrier (3-6) is formed
15) reflection electromagnetic wave signal (17), (25),
Analysis (33) electromagnetic wave signal (17) detected, (25).
2. according to the method described in claim 1, wherein, the conduction bearing carrier (3-6) is made of nonmetallic materials.
3. according to the method described in claim 1, wherein, the conduction bearing carrier (3-6) is made of composite material, described multiple
Condensation material includes the conductive reinforcement fibers (F) in polymer substrate (m), and the reinforcing fiber (F) is preferably carbon fiber.
4. the method according to any one of preceding claims 1-3, wherein provide (35) for determine ropes (1),
(22) one or more parameters of state.
5. according to the method described in claim 4, wherein, providing (35) about damage position and/or the letter of impedance mismatching size
Breath.
6. the information of the seriousness of (35) for quantifying defect is provided according to the method described in claim 5, wherein, it is described to lack
Fall into such as fibre damage.
7. the method according to any one of preceding claims 4-6, wherein receive for determine ropes (1),
(22) after one or more of parameters of state, status monitoring movement is executed.
8. the method according to any one of preceding claims 1-7, wherein the method also includes following steps, are used for
Improve the electrical contact between analyzer module (8) and conductive bearing carrier (3-6):
The end of (37) ropes (1), (22) is cut,
The non-conducting material around (38) carbon fiber (32) is removed,
The fiber exposed with metal coating (39), the metal such as copper or nickel, and
By the connecting interfaces (10-13) of analyzer module (8) welding (40) to ropes (1), (22) end it is coated
In exposed fibers.
9. the method according to any one of preceding claims 1-7, wherein the method also includes following steps, are used for
Improve the electrical contact between analyzer module (8) and conductive bearing carrier (3-6):
The end of (37) ropes (1), (22) is cut,
The non-conducting material around (38) carbon fiber (32) is removed, and
The connecting interface (10-13) of analyzer module (8) is clamped to ropes (1), in the exposed fibers of (22) end.
10. the method according to any one of preceding claims 1-7, wherein the method also includes following steps, are used for
Improve the electrical contact between analyzer module (8) and conductive bearing carrier (3-6):
The end of (37) ropes (1), (22) is cut,
The non-conducting material around (38) carbon fiber (32) is removed,
The fiber exposed with metal coating (39), the metal such as copper or nickel,
The connecting interface (10-13) of analyzer module (8) is clamped to the coated exposure of ropes (1), (22) end
On fiber.
11. the state monitoring apparatus of a kind of ropes (1) for lifting means, (22), the ropes (1), (22)
Including non-conductive coating layer (2) and for carry be applied in their longitudinal direction ropes (1), load on (22) it is multiple
Adjacent conductive bearing carrier (3-6), the multiple adjacent conductive bearing carrier (3-6) is embedded in coating (2) and that
This in parallel and be parallel to ropes (1), (22) longitudinal direction extend, the coating (2) forms ropes
(1), the surface of (22) and extend between adjacent bearing carrier (3-6), thus by adjacent bearing carrier (3-6) each other every
From described device includes control system (7), and the control system (7) includes analyzer module (8), for generating the electricity propagated
Magnetostatic wave signal and the electromagnetic wave signal of propagation is inserted at least one parallel conductive formed by the conductive bearing carrier (3-6)
Body transmission line (14-15) and carry out described at least one that the freely conductive bearing carrier (3-6) is formed for detection and analysis
The reflection electromagnetic wave signal of a parallel conductor transmission line (14-15).
12. condition checkout gear according to claim 11, wherein the conduction bearing carrier (3-6) is by non-metallic material
Material is made.
13. condition checkout gear according to claim 11, wherein the conduction bearing carrier (3-6) is by composite material
It is made, the composite material includes the conductive reinforcement fibers (F) in polymer substrate (m), and the reinforcing fiber (F) is preferably carbon
Fiber.
14. the condition checkout gear according to any one of preceding claims 1-13, wherein the analyzer module (8)
One or more parameters for determining the state of ropes (1), (22) are provided.
15. the state monitoring apparatus according to any one of preceding claims 11-14, wherein according to the present invention
Analyzer module (8) is signal generator/analyzer module (8), network analyser unit (8), scalar network analyzer unit
(8) or vector network analyzer unit (8).
16. state monitoring apparatus according to claim 14 or 15, wherein the control system (7) includes status monitoring
Unit (9), for monitoring the one or more parameters provided by analyzer module (8), to determine ropes (1), (22)
State.
17. the state monitoring apparatus according to any one of preceding claims 11-16, wherein described device includes connection
Interface (10-13), for analyzer module (8) to be connected to conductive bearing carrier in ropes (1), the first end of (22)
(3-6)。
18. the condition checkout gear according to any one of preceding claims 11-17, wherein described device includes one
Or multiple extra conductors (210-214), continuously extend in ropes (1), the whole length of (22).
19. the state monitoring apparatus according to any one of preceding claims 11-17, wherein one or more of attached
Add conductor (210-214) and conductive bearing carrier (3-6) material having the same.
20. state monitoring apparatus according to claim 17, wherein described device includes additional connecting interface, is used for
Ropes (1), (22) the other end (16) at analyzer module (8) is connected to conductive bearing carrier.
21. the state monitoring apparatus according to any one of preceding claims 11-18, wherein described device includes arrangement
At least one impedance matching element (200), (205) at the other end (16) of the ropes (1), (22), it is described extremely
Few impedance matching element (200), (205) are connected between the end of the bearing carrier (3-6), for match it is described extremely
The impedance of a few parallel conductor transmission line (14-15).
22. the state monitoring apparatus according to any one of preceding claims 11-19, wherein detecting in addition to repeating
When having reflection electromagnetic wave signal (17) of stable amplitude except peak value (18), (19), the analyzer module (8) provides and is used for
The state for determining ropes (1) is flawless one or more parameters.
23. the state monitoring apparatus according to any one of preceding claims 11-19, wherein detecting with defect
When indicating reflection electromagnetic wave signal (25) of peak value (26-30), the analyzer module (8) is provided for determining ropes
(22) one or more parameters of state faulty and for determining ropes (22) defect type and state.
24. the state monitoring apparatus according to any one of preceding claims 11-21, wherein the analyzer module (8)
Information about damage position and/or impedance mismatching size is provided.
25. state monitoring apparatus according to claim 22, wherein the analyzer module (8) is provided for quantifying to lack
The information of seriousness is fallen into, the defect is, for example, fibre damage.
26. state monitoring apparatus described in any one of 1-23 according to claim 1, wherein the ropes (1), (22)
Be it is band-like, i.e., width direction is bigger than thickness direction.
27. the state monitoring apparatus according to any one of preceding claims 11-24, wherein receiving for determining
When ropes (1), one or more of parameters of the state of (22), the monitoring unit (9) executes status monitoring movement.
28. the state monitoring apparatus according to any one of preceding claims 11-25, wherein the analyzer (8) passes through
Change signal form, signal amplitude and/or signal frequency to execute multiple measurements.
29. state monitoring apparatus according to claim 26, wherein the analyzer (8) be distorted for reaction
With the measurement of attenuation effect.
30. the state monitoring apparatus according to claim 26 or 27, wherein the analyzer (8) carries out flat for matching
Column conductor transmission line (14), (15) impedance measurement.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
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EP16204611.4 | 2016-12-16 | ||
EP16204611.4A EP3336036B1 (en) | 2016-12-16 | 2016-12-16 | Method and arrangement for condition monitoring of a hoisting rope of a hoisting apparatus |
PCT/EP2017/082835 WO2018109092A2 (en) | 2016-12-16 | 2017-12-14 | Method and arrangement for condition monitoring of a hoisting rope of a hoisting apparatus |
Publications (2)
Publication Number | Publication Date |
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CN110072795A true CN110072795A (en) | 2019-07-30 |
CN110072795B CN110072795B (en) | 2021-06-04 |
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CN201780076495.8A Active CN110072795B (en) | 2016-12-16 | 2017-12-14 | Method and arrangement for condition monitoring of a hoisting rope of a hoisting device |
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US (1) | US11414301B2 (en) |
EP (1) | EP3336036B1 (en) |
CN (1) | CN110072795B (en) |
WO (1) | WO2018109092A2 (en) |
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US11414301B2 (en) | 2022-08-16 |
WO2018109092A2 (en) | 2018-06-21 |
EP3336036A1 (en) | 2018-06-20 |
CN110072795B (en) | 2021-06-04 |
EP3336036B1 (en) | 2021-02-03 |
US20190256324A1 (en) | 2019-08-22 |
WO2018109092A3 (en) | 2018-08-16 |
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